JP7498444B2 - Surgical support robot and surgical support robot system - Google Patents

Description

The present invention relates to a surgery support robot and a surgery support robot system , and more particularly to a surgery support robot and a surgery support robot system that are equipped with an operating tool for operating an arm.

Surgery support robots are known in the past (see, for example, Patent Document 1).

The above-mentioned Patent Document 1 discloses a robot system (surgery support robot) including an articulated probe, a surgical instrument, and a controller (hereinafter referred to as an arm). The surgical instrument is provided at the tip of the articulated probe. The arm is configured to operate (move) the articulated probe and the surgical instrument. The robot system is also provided with a joystick. When an operator operates the joystick, a signal for operating the surgical instrument is output to the arm. The displacement, speed, and acceleration of the surgical instrument are controlled according to the displacement (tilt) of the joystick. The joystick is disposed at a position separated from the arm (articulated probe, surgical instrument).

JP 2019-162427 A

However, in a robot system (surgery support robot) such as that in Patent Document 1, during surgery, the surgical instrument is operated by operating a joystick that is positioned away from the arm. Meanwhile, in the preparation stage before surgery, the arm is moved to move the surgical instrument close to the patient. In this case, in a robot system such as that in Patent Document 1, because the joystick is positioned away from the arm, there is a problem in that it may be difficult to move the arm with the joystick to move the surgical instrument close to the patient.

The present invention has been made to solve the above-mentioned problems, and one object of the present invention is to provide a surgical support robot and a surgical support robot system whose arms can be easily operated using an operating tool.

In order to achieve the above-mentioned object, a surgical support robot according to one aspect of the present invention comprises an arm section consisting of a robot arm having a plurality of joints and a plurality of first motors for driving the plurality of joints, and an arm equipped with a translational movement mechanism to which a medical instrument is attached and which causes a tip link section having a holder including a second motor for driving the medical instrument to translate relatively to the arm section, and an operation section provided on the tip link section of the translational movement mechanism, wherein the operation section can be operated by an operator with the fingers of one hand holding the outer peripheral surface of the operation section, and includes a joystick that, when operated with the fingers of the one hand, drives the plurality of first motors to move the arm and thereby move the medical instrument.

In the surgical support robot according to one aspect of the present invention, as described above, the operating unit is provided on the arm. This allows the operator to operate the operating tool in the vicinity of the arm, making it easy to operate the arm using the operating tool.

In addition, when the operating unit is provided on an arm, if the arm moves relatively quickly (abruptly) in response to the operation of the operating tool by the operator, the operator's movement may not be able to keep up with the sudden movement of the arm. Specifically, while the arm moves, the operator's hand holding the operating tool is unable to keep up with the movement of the arm and remains stationary, or moves at a slower speed than the movement speed of the arm. In this case, the amount of operation of the operating tool changes against the operator's intention, and the operation direction of the arm changes against the operator's intention. As a result, the movement direction of the arm changes abruptly. Conversely, even if the movement speed of the arm suddenly decreases, the operation direction of the operating tool changes against the operator's intention. This state is repeated repeatedly, causing the arm to vibrate.

As described above, the operation unit includes an enable switch that allows the arm to move when pressed, and an operating tool that controls the movement direction of the arm, and the enable switch and operating tool are configured to be arranged at a distance from each other within a range that can be operated by the fingers of one hand of the operator on the operation unit. As a result, the operating tool that controls the movement direction of the arm can be operated by the operator's fingers with the enable switch pressed, so the distance between the operator's fingers operating the operating tool and the fingers pressing the enable switch is kept approximately constant. In other words, even if the arm moves relatively quickly, the distance between the operator's fingers gripping the operation unit and the fingers operating the operation unit is kept approximately constant. As a result, even if the arm moves relatively quickly, the state of the operator's fingers relative to the operation unit is unlikely to change, and the operation direction of the arm by the operation unit is unlikely to change. As a result, even if the arm moves relatively quickly, it is possible to suppress vibration of the arm caused by a change in the operation direction of the operating tool.

According to the present invention, as described above, the arm can be easily operated using the operating tool.

1 is a diagram showing a configuration of a surgical operation system according to an embodiment of the present invention. 1 is a diagram showing a configuration of a medical manipulator according to an embodiment of the present invention. 1A and 1B are diagrams showing a configuration of an arm of a medical manipulator according to an embodiment of the present invention. FIG. 2 is a perspective view showing a configuration of an operation unit of the medical manipulator according to the embodiment of the present invention. FIG. 2 is a side view showing the configuration of an operation unit of the medical manipulator according to the embodiment of the present invention. 1 is a diagram showing a state in which an operator grips an operating section of a medical manipulator according to an embodiment of the present invention. FIG. FIG. 13 is a diagram for explaining translational movement of the arm. FIG. 13 is a diagram for explaining the rotational movement of the arm. FIG. 2 is a block diagram showing a configuration of a control unit of a medical manipulator according to an embodiment of the present disclosure. FIG. 2 is a diagram showing a control block of a control unit of a medical manipulator according to an embodiment of the present disclosure.

Below, an embodiment of the present invention will be described with reference to the drawings.

The configuration of a surgical system 100 according to this embodiment will be described with reference to Figures 1 to 10. The surgical system 100 includes a medical manipulator 1, which is a patient P-side device, and a remote control device 2, which is an operator-side device for operating the medical manipulator 1. The medical manipulator 1 includes a medical cart 3 and is configured to be movable. The remote control device 2 is disposed at a position separated from the medical manipulator 1, and the medical manipulator 1 is configured to be remotely operated by the remote control device 2. The surgeon inputs a command to the remote control device 2 to cause the medical manipulator 1 to perform a desired operation. The remote control device 2 transmits the input command to the medical manipulator 1. The medical manipulator 1 operates based on the received command. The medical manipulator 1 is disposed in an operating room, which is a sterilized sterile field. The medical manipulator 1 is an example of a "surgery support robot" in the claims.

The remote control device 2 is placed, for example, inside or outside an operating room. The remote control device 2 includes an operating manipulator arm 21, an operating pedal 22, a touch panel 23, a monitor 24, a support arm 25, and a support bar 26. The operating manipulator arm 21 constitutes an operating handle for the surgeon to input commands. The monitor 24 is a scope-type display device that displays an image captured by an endoscope. The support arm 25 supports the monitor 24 so that the height of the monitor 24 matches the height of the surgeon's face. The touch panel 23 is placed on the support bar 26. The medical manipulator 1 can be operated by the remote control device 2 by detecting the surgeon's head with a sensor (not shown) provided near the monitor 24. The surgeon operates the operating manipulator arm 21 and the operating pedal 22 while visually checking the affected area through the monitor 24. This inputs commands to the remote control device 2. The commands input to the remote control device 2 are transmitted to the medical manipulator 1.

The medical cart 3 is provided with a control unit 31 that controls the operation of the medical manipulator 1, and a storage unit 32 that stores programs for controlling the operation of the medical manipulator 1. Based on commands input to the remote control device 2, the control unit 31 of the medical cart 3 controls the operation of the medical manipulator 1.

The medical cart 3 is also provided with an input device 33. The input device 33 is configured to receive operations for moving and changing the posture of the positioner 40, arm base 50, and multiple arms 60, mainly for preparation of surgery before the procedure.

As shown in Figures 1 and 2, the medical manipulator 1 is placed in an operating room. The medical manipulator 1 includes a medical cart 3, a positioner 40, an arm base 50, and a plurality of arms 60. The arm base 50 is attached to the tip of the positioner 40. The arm base 50 has a relatively long rod shape (long shape). In addition, the base of each of the plurality of arms 60 is attached to the arm base 50. The plurality of arms 60 are configured to be able to take a folded position (storage position). The arm base 50 and the plurality of arms 60 are used covered with a sterile drape (not shown).

The positioner 40 is, for example, a seven-axis articulated robot. The positioner 40 is disposed on the medical cart 3. The positioner 40 is configured to move the position of the arm base 50 in three dimensions.

The positioner 40 also includes a base portion 41 and a number of link portions 42 connected to the base portion 41. The link portions 42 are connected to each other by joint portions 43.

As shown in FIG. 1, a medical instrument 4 is removably attached to the tip of each of the multiple arms 60. The medical instrument 4 includes, for example, a replaceable instrument, an endoscope assembly (not shown), etc.

As shown in FIG. 3, the instrument as the medical tool 4 is provided with a driven unit 4a driven by a servo motor M2 provided on a holder 71 of an arm 60. An end effector 4b is provided at the tip of the instrument. The end effector 4b includes, as instruments having joints, forceps, scissors, grabbers, needle holders, microdissectors, stable appliers, tackers, suction and cleaning tools, snare wires, and clip appliers. The end effector 4b also includes, as instruments not having joints, cutting blades, cauterizing probes, cleaners, catheters, and suction orifices. The medical tool 4 also includes a shaft 4c connecting the driven unit 4a and the end effector 4b. The driven unit 4a, the shaft 4c, and the end effector 4b are arranged along the Z direction.

Next, the configuration of the arm 60 will be described in detail.

As shown in FIG. 3, the arm 60 includes an arm section 61 (a base section 62, a link section 63, and a joint section 64) and a translation mechanism section 70 provided at the tip of the arm section 61. The arm 60 is configured so that the tip side of the arm 60 can be moved three-dimensionally relative to the base side (arm base 50) of the arm 60. Note that the multiple arms 60 have the same configuration.

In this embodiment, the translational movement mechanism 70 is configured to have the medical instrument 4 attached thereto and to translate the medical instrument 4 relative to the arm 61. Specifically, the translational movement mechanism 70 is provided with a holder 71 that holds the medical instrument 4. The holder 71 houses a servo motor M2 (see FIG. 9). The servo motor M2 is configured to rotate a rotating body provided in the driven unit 4a of the medical instrument 4. The end effector 4b is operated by rotating the rotating body of the driven unit 4a.

The arm 60 is configured to be detachable from the arm base 50.

The arm unit 61 is composed of a seven-axis articulated robot arm. The arm unit 61 also includes a base unit 62 for attaching the arm unit 61 to the arm base 50, and a number of link units 63 connected to the base unit 62. The multiple link units 63 are connected to each other by joint units 64.

The translational movement mechanism 70 is configured to translate the holder 71 along the Z direction, thereby translating the medical instrument 4 attached to the holder 71 along the Z direction (the direction in which the shaft 4c extends). Specifically, the translational movement mechanism 70 includes a base end link part 72 connected to the tip of the arm part 61, a tip end link part 73, and a connecting link part 74 provided between the base end link part 72 and the tip end link part 73. The holder 71 is also provided on the tip end link part 73.

The connecting link portion 74 of the translational movement mechanism 70 is configured as a speed-doubling mechanism that moves the tip side link portion 73 relative to the base side link portion 72 along the Z direction. The tip side link portion 73 is moved relative to the base side link portion 72 along the Z direction, so that the medical instrument 4 provided on the holder 71 moves translationally along the Z direction. The tip of the arm portion 61 is connected to the base side link portion 72 so as to rotate the base side link portion 72 about an axis in the X direction perpendicular to the Z direction.

In this embodiment, as shown in FIG. 4, the medical manipulator 1 includes an operation unit 80 provided on the arm 60. The operation unit 80 includes an enable switch 81, a joystick 82 for operating the movement of the medical instrument 4 by the arm 60, and a switch unit 83 for operating the movement of the medical instrument 4 by the arm 60. The enable switch 81 permits the movement of the arm 60 by the joystick 82 and the switch unit 83, and is in a state in which the movement of the arm 60 is permitted when the enable switch 81 is pressed. The joystick 82 controls (operates) the movement direction and movement speed of the arm 60. The enable switch 81 and the joystick 82 are arranged in the operation unit 80 at a distance within a range that can be operated by the fingers of one hand of the operator O. The operation unit 80 is operated by the operator O (nurse, engineer, etc.) by holding the operation unit 80. The operation unit 80 is configured to be operable by the operator O's finger when the operator O holds the operation unit 80 and presses the enable switch 81 to allow the arm 60 to move. The joystick 82 and the switch unit 83 are examples of the "operation tool" in the claims.

Specifically, the enable switch 81 is configured as a push button switch that is pressed by the finger of the operator O. Pressing the enable switch 81 makes it possible to control the energization of the servo motors M1 to M3 (see FIG. 9) (control to drive the servo motors M1 to M3). In other words, only while the enable switch 81 is pressed can the arm 60 be controlled to move.

The joystick 82 is configured to be operated by being tilted by the finger of the operator O. The arm 60 is controlled to move according to the direction and angle at which the joystick 82 is tilted. The operator O can tilt the joystick 82 by placing his/her finger against the tip 82a of the joystick 82 and moving his/her finger. The input of a signal resulting from the operation of the joystick 82 is accepted only while the enable switch 81 is pressed. In other words, when the enable switch 81 is not pressed, the arm 60 will not move even if the joystick 82 is operated.

In this embodiment, the enable switch 81 is provided on the outer peripheral surface 80a of the operation unit 80, and the operator O grasps the outer peripheral surface 80a of the operation unit 80 and presses the enable switch 81 to permit the movement of the arm 60. As shown in FIG. 5, a pair of enable switches 81 are provided on both sides of the outer peripheral surface 80a of the operation unit 80. Specifically, the cross section of the operation unit 80 has a substantially rectangular shape, and the pair of enable switches 81 are provided on the opposing surfaces 80b of the operation unit 80. In detail, the operation unit 80 has a substantially prismatic shape, and the pair of enable switches 81 are provided on the side surface (surface 80b along the longitudinal direction) of the substantially prismatic operation unit 80. The operator O grasps the outer peripheral surface 80a of the operation unit 80 and presses at least one of the enable switches 81 provided on both sides of the outer peripheral surface 80a of the operation unit 80 to permit the movement of the arm 60.

This reduces the burden on the operator O and improves convenience for the operator O by eliminating the need to press both enable switches 81 provided on both sides of the outer circumferential surface 80a of the operating unit 80.

In this embodiment, as shown in FIG. 5, the joystick 82 is provided on the end surface 80c intersecting with the outer circumferential surface 80a of the operation unit 80. The joystick 82 is arranged in a position that can be operated by the operator O's fingers when the operator O holds the outer circumferential surface 80a of the operation unit 80 and presses the enable switch 81 so that the arm 60 is allowed to move. For example, as shown in FIG. 6, the operator O operates the joystick 82 provided on the end surface 80c of the operation unit 80 with the index finger of the operator O while holding down the pair of enable switches 81 provided on the outer circumferential surface 80a of the operation unit 80 with the thumb and middle finger of the operator O. This makes it possible to easily maintain a substantially constant distance between the thumb and middle finger of the operator O holding the operation unit 80 and the index finger operating the joystick 82. Note that which fingers are used to operate the enable switch 81 and the joystick 82 is not limited to the above example.

In this embodiment, the joystick 82 is configured to operate the movement of the medical instrument 4 by the arm 60 so that the tip 4d (see FIG. 3) of the medical instrument 4 moves on a predetermined plane, or to operate the movement of the medical instrument 4 by the arm 60 so that the tip 4d of the medical instrument 4 rotates around the tip 4d of the medical instrument 4. The operation unit 80 also includes a switch unit 83 for operating the movement of the medical instrument 4 by the arm 60 so that the tip 4d of the medical instrument 4 moves along the longitudinal direction of the medical instrument 4. The predetermined plane on which the tip 4d of the medical instrument 4 moves is a plane parallel to the end face 80c of the operation unit 80 (the X-Y plane in FIG. 4). The longitudinal direction of the medical instrument 4 is the Z direction perpendicular to the X-Y plane in FIG. 4. The coordinates represented by the X-axis, Y-axis, and Z-axis in FIG. 4 are called the tool coordinate system (or the base coordinate system). In addition, when the switch unit 83 is pressed while the enable switch 81 is pressed (a state in which movement of the medical instrument 4 by the arm 60 is permitted), the tip 4d of the medical instrument 4 is moved along the longitudinal direction of the medical instrument 4.

A pair of switch units 83 are provided on both sides of the outer circumferential surface 80a of the operating unit 80. When the operator O grasps the outer circumferential surface 80a of the operating unit 80 and presses at least one of the switch units 83 provided on both sides of the outer circumferential surface 80a of the operating unit 80, the translational movement mechanism unit 70 translates the medical instrument 4.

In this embodiment, the joystick 82 is configured such that the moving speed changes depending on the tilted state, and the moving speed of the tip 4d of the medical instrument 4 on a specified plane is maximized when the joystick 82 is maximally tilted. The time required for the operator O to press the switch unit 83 and for the moving speed of the tip 4d of the medical instrument 4 along the longitudinal direction perpendicular to the specified plane of the tip 4d of the medical instrument 4 to reach its maximum is longer than the time required for the operator O to operate the joystick 82 and for the moving speed of the tip 4d of the medical instrument 4 to reach its maximum. In other words, the tip 4d of the medical instrument 4 is moved at a relatively high speed by operating the joystick 82. In contrast, the speed at which the tip 4d of the medical instrument 4 is moved by operating the switch unit 83 is relatively low.

In this embodiment, the switch unit 83 includes a switch unit 83a that moves the tip 4d of the medical instrument 4 in the direction parallel to the longitudinal direction of the medical instrument 4, in which the medical instrument 4 is inserted into the patient P, and a switch unit 83b that moves the tip 4d of the medical instrument 4 in the direction opposite to the direction in which the medical instrument 4 is inserted into the patient P. Both the switch unit 83a and the switch unit 83b are configured as push button switches. Both the switch unit 83a and the switch unit 83b have a substantially circular shape.

A pivot button 85 is provided adjacent to the enable switch 81 on the surface 80b of the operation unit 80. The pivot button 85 is configured to set a pivot point. The pivot point is the fulcrum around which the arm 60 moves. An adjustment button 86 is provided on the surface 80b of the operation unit 80 to optimize the position of the arm 60.

In addition, in this embodiment, before the pivot position PP is set, the switch unit 83 is operated to move the arm unit 61, thereby translating the tip 4d of the medical instrument 4. After the pivot position PP is set, the switch unit 83 is operated to move the arm unit 61, thereby translating the tip 4d of the medical instrument 4 until the tip 4d of the medical instrument 4 moves a predetermined distance from the pivot position PP. Then, after the tip 4d of the medical instrument 4 moves a predetermined distance from the pivot position PP, the translational movement mechanism unit 70 moves, thereby translating the tip 4d of the medical instrument 4. In other words, after the tip 4d of the medical instrument 4 moves a predetermined distance from the pivot position PP, the arm unit 61 is not moved and only the translational movement mechanism unit 70 is moved.

In this embodiment, as shown in FIG. 4, the operation unit 80 includes a mode switching button 84 for switching between a translational movement mode in which the tip 4d of the medical instrument 4 attached to the arm 60 moves translationally within a predetermined plane (see FIG. 7) and a rotational movement mode in which the tip 4d of the medical instrument 4 moves rotationally around the tip 4d of the medical instrument 4 (see FIG. 8). In the operation unit 80, the mode switching button 84 is disposed near the joystick 82. Specifically, the mode switching button 84 is disposed adjacent to the joystick 82 on the end surface 80c of the operation unit 80. The mode switching button 84 is a push button switch. A mode indicator 84a is disposed near the mode switching button 84. The current mode (translational movement mode or rotational movement mode) is notified by turning on or off the mode indicator 84a.

As shown in FIG. 7, in the translational movement mode in which the tip 4d of the medical instrument 4 is translated, the arm 60 is moved by the joystick 82 so that the tip 4d of the medical instrument 4 moves on the X-Y plane. Also, as shown in FIG. 8, in the rotational movement mode in which the tip 4d of the medical instrument 4 is rotated around the tip 4d, when the pivot position PP is not taught, the arm 60 is moved by the joystick 82 so that the medical instrument 4 rotates around the tip 4d of the end effector 4b, and when the pivot position PP is taught, the arm 60 is moved so that the medical instrument 4 rotates around the pivot position PP. Note that after the pivot point (pivot position PP) is set, the translational movement mode cannot be set. Also, when the shaft 4c of the medical instrument 4 is inserted into the trocar T, the medical instrument 4 is rotated while the shaft 4c is restrained around the pivot position PP.

That is, the joystick 82 is configured to operate the arm 60 in one of two modes: a translational movement mode in which the arm 60 moves the medical instrument 4 so that the tip 4d of the medical instrument 4 attached to the arm 60 moves translationally within a predetermined plane (see FIG. 7), and a rotational movement mode in which the arm 60 moves the medical instrument 4 so that the medical instrument 4 moves rotationally around the tip 4d of the medical instrument 4 (see FIG. 8).

In this embodiment, as shown in FIG. 3, the operation unit 80 is provided on the translational movement mechanism 70. The operation unit 80 is provided on the translational movement mechanism 70 so as to be adjacent to the medical instrument 4 attached to the translational movement mechanism 70. Specifically, the operation unit 80 is provided on the distal link portion 73 of the translational movement mechanism 70. The operation unit 80 is disposed so as to be adjacent to the driven unit 4a of the medical instrument 4.

As shown in FIG. 9, the arm 60 is provided with a plurality of servo motors M1, an encoder E1, and a reducer (not shown) to correspond to the plurality of joints 64 of the arm portion 61. The encoder E1 is configured to detect the rotation angle of the servo motor M1. The reducer is configured to decelerate the rotation of the servo motor M1 to increase the torque.

As shown in FIG. 9, the translational movement mechanism 70 includes a servo motor M2 for rotating a rotor provided in the driven unit 4a of the medical instrument 4, a servo motor M3 for translating the medical instrument 4, an encoder E2, an encoder E3, and a reducer (not shown). The encoders E2 and E3 are configured to detect the rotation angles of the servo motors M2 and M3, respectively. The reducers are configured to decelerate the rotation of the servo motors M2 and M3 to increase the torque.

The positioner 40 is also provided with a plurality of servo motors M4, an encoder E4, and a reducer (not shown) to correspond to the plurality of joints 43 of the positioner 40. The encoder E4 is configured to detect the rotation angle of the servo motor M4. The reducer is configured to reduce the rotation speed of the servo motor M4 to increase the torque.

The medical cart 3 is also provided with a servo motor M5 that drives each of the multiple front wheels (not shown) of the medical cart 3, an encoder E5, and a reducer (not shown). The encoder E5 is configured to detect the rotation angle of the servo motor M5. The reducer is configured to decelerate the rotation of the servo motor M5 to increase the torque.

The control unit 31 of the medical cart 3 includes an arm control unit 31a that controls the movement of the multiple arms 60 based on commands, and a positioner control unit 31b that controls the movement of the positioner 40 and the drive of the front wheels (not shown) of the medical cart 3 based on commands. A servo control unit C1 for controlling a servo motor M1 for driving the arm 60 is electrically connected to the arm control unit 31a. In addition, an encoder E1 for detecting the rotation angle of the servo motor M1 is electrically connected to the servo control unit C1.

The arm control unit 31a is also electrically connected to a servo control unit C2 for controlling a servo motor M2 for driving the medical instrument 4. The servo control unit C2 is also electrically connected to an encoder E2 for detecting the rotation angle of the servo motor M2. The arm control unit 31a is also electrically connected to a servo control unit C3 for controlling a servo motor M3 for translating the translational movement mechanism unit 70. The servo control unit C3 is also electrically connected to an encoder E3 for detecting the rotation angle of the servo motor M3.

Then, the operation command input to the remote control device 2 is input to the arm control unit 31a. The arm control unit 31a generates a position command based on the input operation command and the rotation angle detected by the encoder E1 (E2, E3), and outputs the position command to the servo control unit C1 (C2, C3). The servo control unit C1 (C2, C3) generates a torque command based on the position command input from the arm control unit 31a and the rotation angle detected by the encoder E1 (E2, E3), and outputs the torque command to the servo motor M1 (M2, M3). As a result, the arm 60 is moved in accordance with the operation command input to the remote control device 2.

In addition, in this embodiment, the control unit 31 (arm control unit 31a) is configured to operate the arm 60 based on an input signal from the joystick 82 of the operation unit 80. Specifically, the arm control unit 31a generates a position command based on the input signal (operation command) input from the joystick 82 and the rotation angle detected by the encoder E1, and outputs the position command to the servo control unit C1. The servo control unit C1 generates a torque command based on the position command input from the arm control unit 31a and the rotation angle detected by the encoder E1, and outputs the torque command to the servo motor M1. As a result, the arm 60 is moved in accordance with the operation command input to the joystick 82.

Here, in this embodiment, the control unit 31 (arm control unit 31a) is configured to perform control to reduce changes in the movement speed of the arm 60 by performing at least one of setting an upper limit value for the input signal from the joystick 82 and smoothing the input signal from the joystick 82. Specifically, the control unit 31 sets an upper limit value for the input signal from the joystick 82, and when an input signal exceeding the upper limit value is input, the control unit 31 controls the movement of the arm 60 using the upper limit value as an input signal. In addition, the control unit 31 smoothes the input signal from the joystick 82, for example, by an LPF (Low-pass filter). Note that, in this embodiment, the control unit 31 both sets an upper limit value for the input signal from the joystick 82 and smoothes the input signal from the joystick 82.
In addition, the control unit 31 (arm control unit 31a) controls the movement of the arm 60 based on the control equation of motion shown in the following mathematical expression.

The control unit 31 (arm control unit 31a) also controls the movement of the arm 60 based on the control block shown in FIG. 10. That is, the control unit 31 (arm control unit 31a) subtracts the product of the velocity (first derivative of x) and the viscosity coefficient c from the input signal F(s) from the joystick 82. The subtracted value is then multiplied by the inertia coefficient 1/m. If the multiplied value (=1/m(F(s)-c×velocity)=acceleration=second derivative of x) exceeds the upper limit, the acceleration is set to the upper limit. The acceleration is then integrated to calculate the velocity (first derivative of x), and the velocity is then integrated to calculate the position X(s).

The positioner control unit 31b is also electrically connected to a servo control unit C4 for controlling a servo motor M4 that moves the positioner 40. The servo control unit C4 is also electrically connected to an encoder E4 for detecting the rotation angle of the servo motor M4. The positioner control unit 31b is also electrically connected to a servo control unit C5 for controlling a servo motor M5 that drives the front wheels (not shown) of the medical cart 3. The servo control unit C5 is also electrically connected to an encoder E5 for detecting the rotation angle of the servo motor M5.

In addition, an operation command related to setting the preparation position, etc. is input from the input device 33 to the positioner control unit 31b. The positioner control unit 31b generates a position command based on the operation command input from the input device 33 and the rotation angle detected by the encoder E4, and outputs the position command to the servo control unit C4. The servo control unit C4 generates a torque command based on the position command input from the positioner control unit 31b and the rotation angle detected by the encoder E4, and outputs the torque command to the servo motor M4. This causes the positioner 40 to move in accordance with the operation command input to the input device 33. Similarly, the positioner control unit 31b moves the medical cart 3 based on the operation command from the input device 33.

Next, the procedure of the treatment using the medical manipulator 1 will be described. In the treatment using the medical manipulator 1, first, the medical cart 3 is moved to a predetermined position in the operating room by the operator O. Next, the operator O operates the touch panel included in the input device 33 to move the arm base 50 by operating the positioner 40 so that the arm base 50 and the operating table 5 or the patient P have a desired positional relationship. In addition, the arm 60 is moved so that the cannula sleeve (a working channel for inserting a surgical instrument or the like into a body cavity) placed on the body surface of the patient P and the medical instrument 4 have a predetermined positional relationship. In addition, the operator O operates the joystick 82 to move the multiple arms 60 to the desired positions. Then, with the positioner 40 stationary, the multiple arms 60 and the medical instrument 4 are operated based on a command from the remote control device 2. In this way, the treatment using the medical manipulator 1 is performed.

[Effects of this embodiment]
In this embodiment, the following effects can be obtained.

In this embodiment, as described above, the operation unit 80 is provided on the arm 60. This allows the operator O to operate the joystick 82 and the switch unit 83 in the vicinity of the arm 60, making it possible to easily operate the arm 60 using an operating tool.

In addition, in this embodiment, as described above, the operation unit 80 includes an enable switch 81 that allows the movement of the arm 60 by being pressed, and a joystick 82 that controls (operates) the movement direction and movement speed of the arm 60, and the enable switch 81 and the joystick 82 are configured to be arranged in the operation unit 80 at a distance within a range that can be operated by the fingers of one hand of the operator O. As a result, the joystick 82 that operates the movement direction and movement speed of the arm 60 can be operated by the fingers of the operator O with the enable switch 81 pressed, so that the distance between the fingers of the operator O that operate the operation unit 80 and the fingers that press the enable switch 81 is kept approximately constant. In other words, even if the arm 60 moves relatively fast, the distance between the fingers of the operator O that hold the joystick 82 and the fingers that operate the operation unit 80 is kept approximately constant. As a result, even if the arm 60 moves relatively fast, the state of the fingers of the operator O relative to the operation unit 80 is unlikely to change, so the direction of the arm 60 by the operation unit 80 is unlikely to change. As a result, even when the arm 60 moves at a relatively high speed, vibration of the arm 60 caused by changes in the direction of the joystick 82 can be suppressed.

In addition, in this embodiment, as described above, the joystick 82 controls the movement direction and movement speed of the arm 60. This makes it possible to suppress vibrations of the arm 60 caused by changes in the direction of the joystick 82 and changes in the amount of operation.

In addition, in this embodiment, as described above, the enable switch 81 allows the movement of the arm 60 when the operator O grasps the outer peripheral surface 80a of the operation unit 80 and presses the enable switch 81. As a result, the operator O can easily press the enable switch 81 to allow the movement of the arm 60 simply by grasping the outer peripheral surface 80a of the operation unit 80 so as to cover it with his/her fingers.

In addition, in this embodiment, as described above, the enable switch 81 allows the movement of the arm 60 by the operator O gripping the outer circumferential surface 80a of the operation unit 80 and pressing at least one of the enable switches 81 provided on both sides of the outer circumferential surface 80a of the operation unit 80. As a result, since the enable switches 81 are provided on both sides of the outer circumferential surface 80a of the operation unit 80, the operator O can be prompted to cover the outer circumferential surface 80a of the operation unit 80 with his/her fingers and grip it. In addition, if the configuration is such that the movement of the arm 60 is permitted by pressing only one of the enable switches 81, the operator O can perform the movement operation of the arm 60 by pressing the enable switch 81 that is easier to press, thereby improving the convenience of operation.

In addition, in this embodiment, as described above, the cross section of the operation unit 80 has a substantially rectangular shape, and the pair of enable switches 81 are each provided on the mutually opposing surfaces 80b of the operation unit 80. As a result, since the pair of enable switches 81 are each provided on the mutually opposing surfaces 80b of the operation unit 80, the operator O can easily press the enable switch 81 by grasping the operation unit 80 so as to sandwich the mutually opposing surfaces 80b.

In this embodiment, as described above, the joystick 82 is provided on the end surface 80c intersecting with the outer peripheral surface 80a of the operation unit 80, and is arranged in a position that can be operated by the operator O's fingers when the operator O grasps the outer peripheral surface 80a of the operation unit 80 and presses the enable switch 81 to allow the movement of the arm 60. This allows the operator O to operate the joystick 82 provided on the end surface 80c intersecting with the outer peripheral surface 80a of the operation unit 80 with the operator O's index finger or the like when the operator O presses the enable switch 81 provided on the outer peripheral surface 80a of the operation unit 80 with the operator O's thumb and middle finger or the like. This allows the operator O to easily maintain a substantially constant distance between the thumb and middle finger, etc., that grasp the operation unit 80 and the index finger that operates the operation unit 80.

In addition, in this embodiment, as described above, the arm 60 includes an arm section 61 consisting of a seven-axis articulated robot arm, and a translational movement mechanism section 70 that is provided at the tip of the arm section 61 and to which the medical instrument 4 is attached, and that translates the medical instrument 4 relative to the arm section 61. As a result, the operation section 80 is disposed in the vicinity of the medical instrument 4 (the translational movement mechanism section 70 to which the medical instrument 4 is attached), so that the operation of moving the arm 60 so as to move the medical instrument 4 to a desired position can be easily performed by the operation section 80.

In addition, in this embodiment, as described above, the operation unit 80 is provided on the translation mechanism 70 so as to be adjacent to the medical instrument 4. This ensures that the operation unit 80 is positioned near the medical instrument 4, making it easier to use the operation unit 80 to move the arm 60 so as to move the medical instrument 4 to a desired position.

In addition, in this embodiment, as described above, the operation unit 80 is provided with a joystick 82 that can be operated by the finger of the operator O. As a result, the joystick 82 can be operated with a relatively small force, so that the joystick 82 can be easily operated by the finger of the operator O when the operator O grasps the outer peripheral surface 80a of the operation unit 80 and presses the enable switch 81 to allow the movement of the arm 60.

In this embodiment, the operation unit 80 further includes a switch unit 83 for operating the arm 60 so that the tip 4d of the medical instrument 4 moves along the longitudinal direction of the medical instrument 4. This allows the arm 60 to be moved three-dimensionally by using the joystick 82 and the switch unit 83 in combination.

In this embodiment, as described above, the joystick 82 controls the movement direction and movement speed of the arm 60, and the medical manipulator 1 further includes a control unit 31 that controls the arm 60 based on an input signal from the joystick 82. The control unit 31 is configured to perform control to reduce changes in the movement speed of the arm 60 by performing at least one of setting an upper limit value for the input signal from the joystick 82 and smoothing the input signal from the joystick 82. As a result, even if the arm 60 moves at a higher speed and the amount of operation of the operator O's finger on the operation unit 80 changes, the control unit 31 performs at least one of setting an upper limit value for the input signal from the joystick 82 and smoothing the input signal from the joystick 82, so that the vibration of the arm 60 caused by the change in the amount of operation of the joystick 82 can be more effectively suppressed.

[Modification]
It should be noted that the embodiments disclosed herein are illustrative and not restrictive in all respects. The scope of the present invention is indicated by the claims, not by the description of the embodiments above, and further includes all modifications (variations) within the meaning and scope of the claims.

For example, in the above embodiment, an example is shown in which the operation unit 80 is provided with a joystick 82 that can be operated by the finger of the operator O, but the present disclosure is not limited to this. For example, an acceleration sensor that can be operated by the finger of the operator O may be provided in the operation unit 80, and the arm 60 may be moved based on an input signal input to the acceleration sensor. Alternatively, a force sensor that can be operated by the finger of the operator O may be provided in the operation unit 80, and the arm 60 may be moved based on an input signal input to the force sensor. In addition, for example, a strain gauge type force sensor or a piezoelectric type force sensor is used as the force sensor. In addition, in addition, a three-axis force sensor that can detect forces and moments in three directions, or a six-axis force sensor that can detect forces and moments in six directions is used as the force sensor.

In addition, in the above embodiment, an example has been shown in which the movement of the arm 60 is permitted by pressing one of the pair of enable switches 81 provided on both sides of the outer circumferential surface 80a of the operating unit 80, but the present disclosure is not limited to this. For example, the movement of the arm 60 may be permitted by pressing both of the pair of enable switches 81 provided on both sides of the outer circumferential surface 80a of the operating unit 80.

In addition, in the above embodiment, an example was shown in which a pair of enable switches 81 are provided on both sides of the outer circumferential surface 80a of the operating unit 80, but the present disclosure is not limited to this. For example, one enable switch 81 may be provided on one side of the outer circumferential surface 80a of the operating unit 80.

In addition, in the above embodiment, an example is shown in which the cross section of the operation unit 80 has a substantially rectangular shape (the operation unit 80 has a substantially prismatic shape), but the present disclosure is not limited to this. For example, the operation unit 80 may have a substantially cylindrical shape.

In the above embodiment, the joystick 82 is provided on the end surface 80c that intersects with the outer peripheral surface 80a of the operation unit 80, but the present disclosure is not limited to this. In the present disclosure, the joystick 82 may be provided in a position that can be operated by the finger of the operator O when the operator O is holding the operation unit 80 so as to press the enable switch 81.

In addition, in the above embodiment, an example has been shown in which the operation unit 80 is provided on the translational movement mechanism unit 70, but the present disclosure is not limited to this. For example, the operation unit 80 may be provided on the arm unit 61.

In addition, in the above embodiment, an example was shown in which the joystick 82 is configured to operate the arm 60 in a mode in which the tip 4d of the medical instrument 4 translates on a predetermined plane (see FIG. 7) and in a mode in which the tip 4d of the medical instrument 4 rotates around the tip 4d of the medical instrument 4 (see FIG. 8), but the present disclosure is not limited to this. For example, the joystick 82 may be configured to operate the arm 60 so that the medical instrument 4 translates along the longitudinal direction of the medical instrument 4.

In addition, in the above embodiment, an example has been shown in which the control unit 31 both sets an upper limit value for the input signal from the joystick 82 and smoothes the input signal from the joystick 82, but the present disclosure is not limited to this. For example, the control unit 31 may perform only one of setting an upper limit value for the input signal from the joystick 82 and smoothing the input signal from the joystick 82.

In addition, in the above embodiment, an example in which four arms 60 are provided is shown, but the present disclosure is not limited to this. The number of arms 60 may be three.

In addition, in the above embodiment, an example was shown in which the arm unit 61 and the positioner 40 were configured from a 7-axis articulated robot, but the present disclosure is not limited to this. For example, the arm 60 and the positioner 40 may be configured from an articulated robot with an axis configuration other than a 7-axis articulated robot (e.g., 6-axis or 8-axis).

1. Medical manipulator (surgical support robot)
4 Medical instrument 31 Control unit 60 Arm 61 Arm unit 70 Translational movement mechanism unit 80 Operation unit 81 Enable switch 82 Joystick (operation tool)
80a: Outer circumferential surface 80b: Surface 80c: End surface 83, 83a, 83b: Switch section O: Operator

Claims (14)

an arm section including a robot arm having a plurality of joints and a plurality of first motors for driving the plurality of joints, and an arm including a translational movement mechanism for moving a distal end link section having a holder including a second motor for driving the medical instrument, in a translational movement relative to the arm section, the distal end link section having a holder including a second motor for driving the medical instrument, the arm including a translational movement mechanism for moving a distal end link section in a translational movement relative to the arm section, the distal end link section having a holder including a second motor for driving the medical instrument, the arm including a translational movement mechanism for moving a distal end link section in a translational movement relative to the arm section, the arm including a translational movement mechanism for moving a distal end link section having a holder including a second motor for driving the medical instrument ...
an operation unit provided on the tip side link unit of the translational movement mechanism,
The operation unit can be operated by an operator with the fingers of one hand gripping the outer peripheral surface of the operation unit, and includes a joystick that, when operated with the fingers of the one hand , drives the multiple first motors to move the arms and thereby move the medical instrument. 2. The surgical support robot according to claim 1 , wherein the translational movement mechanism includes a base-end link portion connected to the arm, and is configured to translate the tip-end link portion relative to the base-end link portion. The surgical support robot according to claim 2 , wherein the translational movement mechanism is a speed-doubling mechanism that translates the distal link portion relative to the proximal link portion. The surgical support robot according to claim 2 or 3 , wherein the base-end link portion is connected to the tip link of the arm portion so as to rotate via one of the plurality of joints. The surgical support robot according to claim 1 , wherein the translational movement mechanism includes a third motor for translationally moving the tip side link portion relative to the arm portion. The surgical support robot according to claim 1 , wherein a cross section of the operation section along a direction perpendicular to a direction in which the shaft of the medical instrument extends has a rectangular shape. The surgical support robot according to any one of claims 1 to 6, wherein the joystick is configured to operate the arm in one of a translational movement mode in which the arm is moved so that the tip of the medical instrument moves translationally on a predetermined plane, and a rotational movement mode in which the arm is moved so that the medical instrument rotates around the tip of the medical instrument, and the translational movement mode and the rotational movement mode are switchable . The surgical support robot according to claim 7 , wherein the operation unit includes a mode switching button for switching between the translational movement mode and the rotational movement mode. The surgical support robot according to claim 7 or 8 , wherein the operation unit includes a mode indicator for identifying the translational movement mode and the rotational movement mode. The surgical support robot according to any one of claims 1 to 9 , wherein the operation unit includes a switch unit for operating the movement of the medical instrument by the arm so that the tip of the medical instrument moves along a longitudinal direction of the medical instrument. 11. The surgical support robot of claim 10, wherein the switch unit includes a first switch unit for operating the movement of the medical instrument by the arm so that a tip of the medical instrument moves toward a first direction along a longitudinal direction of the medical instrument, and a second switch unit for operating the movement of the medical instrument by the arm so that the tip of the medical instrument moves toward a second direction opposite to the first direction along the longitudinal direction of the medical instrument. A surgical support robot according to any one of claims 1 to 11, and a remote control device,
A surgical support robot system, wherein the multiple first motors of the arm and the second motor of the holder are driven based on commands from the remote control device to operate the medical instrument and the arm. 13. The surgical support robot system according to claim 12, wherein the surgical support robot is the surgical support robot according to claim 5, and the third motor is driven based on a command from the remote control device to operate the translational movement mechanism. 14. The surgical support robot system according to claim 12, wherein the remote control device includes an operation manipulator arm, and the command is input via the operation manipulator arm.

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